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1287 Comparison of multiplex immunofluorescence and H&E-based approaches for characterization of the tumor microenvironment

September, 09, 2024 | Select Oncology Journal Articles

Background

Predictive models applied to digital pathology images show promise for the rapid and objective analysis of patient samples to identify features of the tumor microenvironment (TME) predictive of treatment response. Here we compare two tissue and cell identification approaches —multiplex immunofluorescence (mIF) and deep learning models applied to H&E-stained slides.

Methods

Adjacent sections from primary or metastatic tumors (n=91) from patients with colorectal, non-small cell lung, ovarian, pancreatic, and breast cancer were stained by mIF and H&E. mIF image analysis was done for tumor-stroma segmentation and to identify necrotic tissue within the pathologist-annotated tumor bed. Cytotoxic T cells, immune cells, and fibroblasts were identified using CD8, CD45, and COL1A1 stain thresholding, respectively. AI-powered TME models developed by PathAI (Boston, MA; commercially available as PathExploreTM) were deployed on the H&E slides for tissue classification (tumor epithelium, stroma, necrosis) and cell identification (cancer cells, lymphocytes, macrophages, plasma cells, fibroblasts).

Tissue and cell features were compared between the approaches. Areas of tumor epithelium, stroma, and necrosis were assessed qualitatively with areas of disagreement undergoing independent pathologist review. The density of CD8+ cells from mIF was compared to lymphocytes from H&E, of CD45+ immune cells from mIF to lymphocytes, macrophages, and plasma cells from H&E, and of COL1A1+ cells from mIF to fibroblasts from H&E, recognizing that these cell populations do not overlap completely.

Results

The mIF and H&E approaches showed good tissue segmentation performance, producing broadly similar annotations, with differences attributable to staining co-occurrence in mIF, lower performance of H&E models on metastatic samples, and disagreement at the tumor bed periphery.

Cell identification showed broad agreement between the density of CD8+ by mIF and lymphocytes by H&E (r=0.66, range 0.30–0.93 by indication), CD45+ cells by mIF with immune cells by H&E (r=0.60, range 0.23–0.87), and COL1A1+ cells by mIF with fibroblasts by H&E (r=0.51, range 0.08–0.56) (figure 1, table 1).

Conclusions

Automated analysis of digital pathology images is a rapidly emerging field with broad potential to analyze pathology tissues accurately and reproducibly across tumor types. PathAI’s TME models are a robust tool to distinguish tissue and cell features from H&E slides, comparable to mIF image analysis, but requiring less effort, time, and expense. Indication-specific differences in cell classifications point to more accurate performance by H&E models than mIF. With additional refinement, these technologies could allow efficient evaluation of large pathology datasets for discovery of novel features to inform biology and patient care.

Abstract 1287 Figure 1

Cell identification comparison between H&E models a mlF image analysis (A) Correlation of lymphocyte density by H&E with CD8+ cell density by mlF; (B) Correlation of immune cell density by H&E with CD45+ cell density by mlF; (C) Correlation of fibroblast densiy by H&E with COL1A1+ cell density by mlF. Colors by indication. The trend line is shown for all indications together. CRC: Colorectal Cancer; NSCLC: Non- Small Cell Lung Cancer; OVR; Ovarian Cancer; PANC: Pancreatic Cancer; TNBC: Triple Negative Breast Cancer

Abstract 1287 Table 1

Cell identification correction between mlF and H&E-based approaches. CRC: Colorectal Cancer; NSCLC: Non-Small Cell Lung Cancer; OVR: Ovarian Cancer; PANC: Pancreatic Cancer; TNBC: Triple Negative Breast Cancer; SE: Standard Error

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